JP4663967B2 - Fuel cell - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a fuel cell provided with an electrolyte / electrode structure provided with electrodes on both sides of an electrolyte and a pair of separators sandwiching the electrolyte / electrode structure.
[0002]
[Prior art]
For example, a polymer electrolyte fuel cell has an electrolyte / electrode structure in which an anode electrode and a cathode electrode are respectively provided on both sides of an electrolyte (electrolyte membrane) made of a polymer ion exchange membrane (cation exchange membrane). , And is sandwiched between separators. This type of fuel cell is usually used as a fuel cell stack by stacking a predetermined number of electrolyte / electrode structures and separators.
[0003]
In this fuel cell, a fuel gas supplied to the anode side electrode, for example, a gas mainly containing hydrogen (hereinafter, also referred to as a hydrogen-containing gas) is ionized on the electrode catalyst, and the cathode side passes through the electrolyte. Move to the electrode side. Electrons generated during that time are taken out to an external circuit and used as direct current electric energy. The cathode side electrode is supplied with an oxidant gas, for example, a gas mainly containing oxygen or air (hereinafter also referred to as an oxygen-containing gas). And oxygen react to produce water.
[0004]
In the above fuel cell, a fuel gas channel (reactive gas channel) for flowing a fuel gas opposite to the anode side electrode and an oxidant gas for flowing the cathode gas facing the cathode side electrode in the plane of the separator. The oxidant gas flow path (reaction gas flow path) is provided. Further, in this type of fuel cell, a communication hole for flowing an oxidant gas and a fuel gas, which are reaction gases, is provided in the reaction gas flow path so as to penetrate in the stacking direction of the electrolyte / electrode structure and the separator. Manifold is adopted.
[0005]
For example, in the solid polymer electrolyte fuel cell disclosed in Patent Document 1, as shown in FIG. 13, an oxidant gas, for example, is formed at one end edge in the arrow X direction of the separator 1 constituting the fuel cell. An oxidant gas supply side communication hole 2a for supplying an oxygen-containing gas and a fuel gas supply side communication hole 3a for supplying a fuel gas, for example, a hydrogen-containing gas, are provided.
[0006]
An oxidant gas discharge side communication hole 2b for discharging oxidant gas and a fuel gas discharge side communication hole 3b for discharging fuel gas are provided at the other end edge of the separator 1 in the arrow X direction. ing. On the surface 1a of the separator 1 facing the cathode side electrode (not shown), for example, an oxidant gas flow path 4 composed of a plurality of grooves extending in the direction of the arrow X is provided. The channel 4 communicates with the oxidant gas supply side communication hole 2a and the oxidant gas discharge side communication hole 2b.
[0007]
[Patent Document 1]
JP 2001-266910 A (paragraph [0025], FIG. 1)
[0008]
[Problems to be solved by the invention]
However, since the oxidant gas supply side communication hole 2a is provided on the right side of one edge of the separator 1 in the direction of the arrow X, the oxidant gas flows vertically from the oxidant gas supply side communication hole 2a (the direction of the arrow X). When the oxidant gas is introduced into the oxidant gas flow path 4, it is difficult to sufficiently supply this oxidant gas particularly near the fuel gas supply side communication hole 3 a (on the left side of one end edge in the arrow X direction). .
[0009]
As a result, the number of passages (a part of the oxidant gas flow path 4) for guiding the oxidant gas from the oxidant gas supply side communication hole 2a to the electrode surface is substantially limited. Pressure loss increases. Therefore, it has been pointed out that the compressor for supplying the oxidant gas is increased in size and the entire equipment cannot be reduced in size and weight. In addition, the reaction gas is not uniformly supplied into the electrode surface, and power generation performance may be reduced.
[0010]
Further, in the separator 1, communication holes are not provided in the two sides 1 b on both ends of the arrow Y direction intersecting the arrow X direction. For this reason, each side 1b is easy to be exposed to the outside air, and dew condensation occurs in the passage on the side 1b side, and a decrease in power generation performance is caused by retention of condensed water.
[0011]
The present invention solves this type of problem, and an object thereof is to provide a fuel cell that can reduce the size of a separator with a simple configuration and can effectively maintain power generation performance.
[0012]
[Means for Solving the Problems]
In the fuel cell according to claim 1 of the present invention, at least a reactive gas, which is an oxidant gas or a fuel gas, is supplied to and discharged from a reactive gas passage formed in the separator surface facing the electrolyte / electrode structure. The separator is provided with a reaction gas supply side communication hole and a reaction gas discharge side communication hole penetrating in the stacking direction, and at least the reaction gas supply side communication hole or the reaction gas discharge side communication hole (hereinafter simply referred to as a communication hole). Is also provided with first and second straight portions that extend in the two-sided direction across the corners of the separator.
[0013]
As described above, since the communication hole includes the first and second linear portions extending in the two sides of the separator, the reaction gas collides with each other when supplied to the reaction gas flow path from different directions, It is uniformly dispersed in the reaction gas flow path. For this reason, it becomes possible to supply reaction gas uniformly and reliably with respect to an electrode surface. In addition, the reaction gas can be supplied to the reaction gas flow path from different directions, and the range of the passage for guiding the reaction gas from the communication hole to the electrode surface is effectively increased as compared with the conventional structure. The reaction gas can be supplied uniformly over the entire region. Therefore, the pressure loss of the reaction gas in the passage is effectively reduced, the compressor for supplying the reaction gas is not increased in size, and the cell structure is reduced in thickness.
[0014]
In addition, the communication holes are arranged around the separator including the corners of the separator, so that the space in the separator surface can be used effectively, and the electrode surface utilization factor of the separator is improved. As a result, the entire fuel cell can be reduced in size and weight.
[0015]
Also The second The first straight portion and the second straight portion are separated from each other across the corner portion of the separator, whereby a rib portion is provided between the first and second straight portions. For this reason, the corner | angular part of a separator is favorably reinforced by the rib part, and the intensity | strength of the said separator improves.
[0016]
further , A hole for inserting a stack fastening bolt or a positioning knock is formed in the hub portion, so that the inside of the separator can be used efficiently, and the entire fuel cell can be easily downsized.
[0017]
Furthermore , The parator is provided with a cooling medium supply side communication hole and a cooling medium discharge side communication hole (hereinafter also simply referred to as a communication hole) penetrating in the stacking direction for supplying and discharging the cooling medium, and also on the reaction gas supply side The communication hole, the reaction gas discharge side communication hole, the cooling medium supply side communication hole, and the cooling medium discharge side communication hole extend around the electrode surface of the electrolyte / electrode structure.
[0018]
Therefore, the electrode surface is not directly cooled by the outside air, and the occurrence of condensation within the electrode surface can be effectively prevented. Accordingly, it is possible to effectively use the humidified water, and it is possible to reduce the amount of condensed water in the electrode surface and prevent the power generation performance from being lowered. In addition, when a sealing member is provided so as to surround each communication hole, there is no portion where the surface pressure of the seal hardly acts in the separator surface, and a uniform sealing surface pressure is applied in the separator surface. Is done.
[0019]
Also , Electric The denatured / electrode structure and the separator are stacked in the horizontal direction. For this reason, a part lower than an electrode surface exists in a communicating hole, and even if condensed water accumulates in the said communicating hole, the inside of a reaction gas flow path will not be filled with condensed water. Therefore, the drainage of condensed water is improved, and water does not accumulate in the electrode surface, so that the power generation performance can be maintained well.
[0020]
further , A buffer portion is provided at the corner of the palator to communicate the reaction gas flow path with the reaction gas supply side communication hole and the reaction gas discharge side communication hole. For this reason, the reaction gas can smoothly flow from the reaction gas supply side communication hole through the reaction gas flow path to the reaction gas discharge side communication hole.
[0021]
Furthermore , The planar shape of the palator is set to be substantially rectangular, and at least one reaction gas supply side communication hole and one reaction gas discharge side communication hole are provided across the respective corners of the diagonal position of the separator. ing. As a result, the reaction gas can flow well in the separator surface.
[0022]
Also , The planar shape of the palator is set to a substantially square shape, and at least one of the reaction gas flow paths is provided in a substantially U shape in the separator surface, and one reaction gas supply side communicates with one of the reaction gas flow paths. The communication hole and the one reaction gas discharge side communication hole are provided across the adjacent corners of the separator. Therefore, a substantially U-shaped reaction gas channel is effectively formed in the separator surface in addition to the substantially straight line shape.
[0023]
further , The planar shape of the palator is set to be substantially square, and in the separator surface, an inlet buffer portion and an outlet buffer portion are provided in the vicinity of at least one reaction gas supply side communication hole and one reaction gas discharge side communication hole. The reaction gas flow path is provided substantially linearly between the inlet buffer portion and the outlet buffer portion. Here, “substantially linear” includes those having undulations in a curved shape or a wave shape along the flow direction of the reaction gas. For this reason, the pressure loss of the reaction gas in the reaction gas flow path is reduced as much as possible, and the outer peripheral dimension of the separator can be set small with respect to the substantially square electrode area. Will improve.
[0024]
Furthermore Small At least the inlet side end position or the outlet side end position of the reaction gas flow path is substantially the same as the end position protruding toward the reaction gas flow path of at least the reaction gas supply side communication hole or the reaction gas discharge side communication hole. Are set at the same position.
[0025]
Here, for example, when the end portion of the reaction gas supply side communication hole protrudes inward of the reaction gas flow channel from the inlet side end portion position of the reaction gas flow channel, from the end portion of the reaction gas supply side communication hole There is a possibility that the reaction gas does not flow into the reaction gas flow path. Therefore, by setting the end position, the reaction gas can be made to flow uniformly in the width direction orthogonal to the flow direction of the substantially straight reaction gas flow path, and a good power generation function can be ensured. It becomes possible.
[0026]
Also , Anti The reaction gas supply side communication hole has a larger opening cross-sectional area than the reaction gas discharge side communication hole. On the reaction gas discharge side communication hole side, the reaction gas is consumed and the reaction gas flow rate is reduced. For this reason, by setting the opening cross-sectional area of the reaction gas discharge side communication hole smaller than the opening cross-sectional area of the reaction gas supply communication hole, the reaction gas can flow smoothly.
[0027]
DETAILED DESCRIPTION OF THE INVENTION
FIG. 1 is an exploded perspective view of a main part of a fuel cell 10 according to the first embodiment of the present invention, and FIG. 2 is a partial cross-sectional view of the fuel cell 10.
[0028]
The fuel cell 10 includes an electrolyte membrane / electrode structure (electrolyte / electrode structure) 14 and rectangular (substantially square) first and second separators 16 and 18 sandwiching the electrolyte membrane / electrode structure 14. Prepare. Between the electrolyte membrane / electrode structure 14 and the first and second separators 16, 18, a seal member 19 such as a gasket is interposed so as to cover the periphery of the communication hole and the outer periphery of the electrode surface (power generation surface) described later. It is disguised.
[0029]
The electrolyte membrane / electrode structure 14 and the first and second separators 16 and 18 are laminated in the horizontal direction (arrow A direction), and the arrow B direction (horizontal direction in FIG. 1) intersecting the lamination direction. The oxidant gas supply side communication hole 20 for supplying an oxidant gas, for example, an oxygen-containing gas, and a fuel gas, for example, a hydrogen-containing gas, are communicated with each other in the stacking direction. A fuel gas discharge side communication hole 22 is provided.
[0030]
The oxidant gas supply side communication hole 20 extends in a long shape in the direction of the arrow B and the direction of the arrow C (two sides) across the corner of the upper edge of the first separator 16. Two straight portions 20a and 20b are integrally provided. The fuel gas discharge side communication hole 22 extends in a long shape in the direction of the arrow B and the direction of the arrow C (two sides) across the corner at the lower end of the one end of the first separator 16. The straight portions 22a and 22b are integrally provided.
[0031]
Fuel gas supply side communication for supplying fuel gas to the other end edge of the electrolyte membrane / electrode structure 14 and the first and second separators 16 and 18 in the direction of arrow B and communicating with each other in the direction of arrow A A hole 24 and an oxidant gas discharge side communication hole 26 for discharging the oxidant gas are provided. The fuel gas supply side communication hole 24 and the oxidant gas discharge side communication hole 26 extend in the arrow B direction and the arrow C direction (two side directions) across the upper and lower corners of the other end edge of the first separator 16, respectively. First straight portions 24a and 26a and second straight portions 24b and 26b extending in a long shape are provided.
[0032]
A cooling medium supply side communication hole 28 for supplying a cooling medium such as pure water, ethylene glycol, or oil is provided at the lower end edge of the electrolyte membrane / electrode structure 14 and the first and second separators 16 and 18. In addition, a cooling medium discharge side communication hole 30 for discharging the cooling medium is provided at the upper edge.
[0033]
The electrolyte membrane / electrode structure 14 includes, for example, a solid polymer electrolyte membrane (electrolyte) 32 in which a perfluorosulfonic acid thin film is impregnated with water, an anode side electrode 34 and a cathode sandwiching the solid polymer electrolyte membrane 32 Side electrode 36. The anode side electrode 34 and the cathode side electrode 36 include a gas diffusion layer made of carbon paper or the like, and an electrode catalyst layer in which porous carbon particles having a platinum alloy supported on the surface are uniformly applied to the surface of the gas diffusion layer. Respectively.
[0034]
As shown in FIGS. 1 and 3, an oxidant gas flow path (reaction) for supplying an oxidant gas along the cathode side electrode 36 is provided on a surface 16 a of the first separator 16 facing the cathode side electrode 36. Gas flow path) 38 is formed. The oxidant gas flow path 38 includes first and second buffer portions 40a and 40b provided close to the oxidant gas supply side communication hole 20 and the oxidant gas discharge side communication hole 26, and the first and second buffers. And a plurality of oxidant gas flow channel grooves 42 communicating with the portions 40a and 40b.
[0035]
The first and second buffer portions 40a and 40b are configured by a plurality of intermittent flow channel grooves, embossed portions, and the like. The oxidant gas flow channel grooves 42 extend in parallel to each other into the surface 16a and are bent.
[0036]
As shown in FIG. 4, a fuel gas channel (reactive gas channel) 48 for supplying fuel gas along the anode side electrode 34 is provided on the surface 18 a of the second separator 18 facing the anode side electrode 34. Is formed. The fuel gas channel 48 includes first and second buffer portions 50a and 50b provided close to the fuel gas supply side communication hole 24 and the fuel gas discharge side communication hole 22, and the first and second buffer portions 50a, And a plurality of oxidant gas passage grooves 52 communicating with 50b.
[0037]
The first and second buffer portions 50a and 50b are configured by a plurality of intermittent flow channel grooves, embossed portions, and the like. The oxidant gas flow channel grooves 52 extend in parallel to each other into the surface 18a and are bent.
[0038]
As shown in FIG. 1, a cooling medium flow path 58 is provided on a surface 18 b opposite to the surface 18 a of the second separator 18. This cooling medium flow path 58 is provided with a predetermined number of straight flow path grooves 60 extending in parallel to the vertical direction (arrow C direction). Both ends of the straight flow channel 60 communicate with the cooling medium supply side communication hole 28 and the cooling medium discharge side communication hole 30. An opening 62 is formed at the center of the seal member 19 corresponding to the anode side electrode 34 and the cathode side electrode 36 (see FIG. 1).
[0039]
The operation of the fuel cell 10 configured as described above will be described below.
[0040]
As shown in FIG. 1, a fuel gas such as a hydrogen-containing gas, an oxidant gas such as air that is an oxygen-containing gas, and a cooling medium such as pure water, ethylene glycol, or oil are supplied into the fuel cell 10. Is done. The oxidant gas supplied to the oxidant gas supply side communication hole 20 communicating in the direction of arrow A is introduced into the oxidant gas flow path 38 of the first separator 16 as shown in FIGS. .
[0041]
Specifically, the oxidant gas supply side communication hole 20 communicates with the first buffer portion 40a constituting the oxidant gas flow path 38, and the oxidant gas supply side communication hole 20 communicates with the first buffer. Oxidant gas is supplied to the portion 40a. The first buffer part 40 a communicates with the oxidant gas flow channel groove 42, and the oxidant gas passes through the oxidant gas flow channel 42 and the cathode side electrode 36 constituting the electrolyte membrane / electrode structure 14. Supplied along.
[0042]
On the other hand, the fuel gas is introduced into the fuel gas flow path 48 from the fuel gas supply side communication hole 24 communicating in the arrow A direction. As shown in FIG. 4, the fuel gas flow path 48 includes a first buffer portion 50a communicating with the fuel gas supply side communication hole 24, and the fuel gas passes through the first buffer portion 50a, and the oxidant It is supplied to the gas channel groove 52. The fuel gas is supplied along the anode-side electrode 34 constituting the electrolyte membrane / electrode structure 14 by flowing through the oxidant gas flow channel 52.
[0043]
Therefore, in each electrolyte membrane / electrode structure 14, the oxidant gas supplied to the cathode side electrode 36 and the fuel gas supplied to the anode side electrode 34 are consumed by an electrochemical reaction in the electrode catalyst layer, Power generation is performed (see FIG. 2).
[0044]
Next, the oxidant gas consumed by being supplied to the cathode side electrode 36 is discharged to the oxidant gas discharge side communication hole 26 through the second buffer portion 40b (see FIG. 3). Similarly, the fuel gas supplied to and consumed by the anode side electrode 34 is discharged to the fuel gas discharge side communication hole 22 through the second buffer portion 50b (see FIG. 4).
[0045]
As shown in FIG. 1, the cooling medium supplied to the cooling medium supply side communication hole 28 is introduced into the cooling medium flow path 58 of the second separator 18. This cooling medium moves vertically upward along the straight flow path groove 60, cools the electrolyte membrane / electrode structure 14, and then is discharged into the cooling medium discharge side communication hole 30.
[0046]
In this case, in the first embodiment, the oxidant gas supply side communication hole 20 extends in the two side directions (arrow B direction and arrow C direction) across the corner of the upper end of the first separator 16. First and second linear portions 20a and 20b extending in a scale shape are provided. For this reason, as shown in FIG. 3, the oxidant gas supplied to the oxidant gas supply side communication hole 20 is introduced from the first straight part 20a to the first buffer part 40a vertically downward, The second straight portion 20b is introduced in the horizontal direction with respect to the first buffer portion 40a.
[0047]
Accordingly, the oxidant gases collide with each other when supplied to the first buffer unit 40a from different directions, and are uniformly dispersed in the first buffer unit 40a. Thereby, in the surface 16a of the 1st separator 16, oxidant gas can be favorably supplied over the whole oxidant gas flow path 38, and substantially the said oxidant gas is supplied to the oxidant gas supply side communication hole 20. The range of the passage leading from the electrode surface 64 to the electrode surface 64 (see FIG. 3) is greatly increased as compared with the conventional structure, and the oxidant gas can be supplied uniformly over the entire region of the electrode surface 64. Therefore, the pressure loss of the oxidant gas in the passage, that is, in the oxidant gas flow path 38 is effectively reduced, the size of the oxidant gas supply compressor and the like is not increased, and the entire fuel cell 10 is Thinning can be easily achieved.
[0048]
Moreover, the oxidant gas supply side communication hole 20, the oxidant gas discharge side communication hole 26, the fuel gas supply side communication hole 24, and the fuel gas are formed on the four sides of the first separator 16 including the corners of the first separator 16. A discharge side communication hole 22, a cooling medium supply side communication hole 28 and a cooling medium discharge side communication hole 30 are provided. Thereby, the in-plane space of the first separator 16 can be used effectively, and the electrode surface utilization factor of the first separator 16 is improved. For this reason, the effect that the size and weight reduction of the fuel cell 10 whole becomes possible is acquired.
[0049]
Furthermore, the periphery of the electrode surface 64 of the first separator 16 is the oxidant gas supply side communication hole 20, the oxidant gas discharge side communication hole 26, the fuel gas supply side communication hole 24, the fuel gas discharge side communication hole 22, and the cooling medium. It is surrounded by the supply side communication hole 28 and the cooling medium discharge side communication hole 30. Therefore, the electrode surface 64 is not directly cooled by the outside air, and the occurrence of condensation within the electrode surface 64 can be effectively prevented. For this reason, it becomes possible to effectively utilize the humidified water of the reaction gas such as the oxidant gas and the fuel gas, reduce the amount of condensed water in the electrode surface 64, and prevent the power generation performance of the fuel cell 10 from deteriorating. can do.
[0050]
Further, the oxidant gas discharge side communication hole 26 is provided with first and second straight portions 26a, 26b extending in two side directions (arrow B direction and arrow C direction), respectively. At that time, in the fuel cell 10, the stacking direction is set to the horizontal direction, and as shown in FIG. 3, the first straight portion 26 a is set to a position lower than the electrode surface 64, and the oxidant gas discharge side communication is set. Even if condensed water stays in the hole 26, the inside of the oxidant gas flow path 38 is not filled with condensed water. As a result, the drainage of condensed water is improved, and water does not accumulate in the electrode surface 64, so that the power generation performance of the fuel cell 10 can be maintained well.
[0051]
In addition, since the same effect as said 1st separator 16 side is acquired in the 2nd separator 18 side, the detailed description is abbreviate | omitted.
[0052]
In the first embodiment, the first buffer units 40a and 50a and the second buffer units 40b and 50b are configured in a rectangular shape, but the present invention is not limited to this. For example, as shown in FIG. 5, a circular first buffer unit 40aa may be employed instead of the first buffer unit 40a. Furthermore, it is possible to select various shapes such as a polygon in addition to a rectangle.
[0053]
FIG. 6 is an explanatory front view of the first separator 70 constituting the fuel cell according to the second embodiment of the present invention. In addition, the same referential mark is attached | subjected to the component same as the 1st separator 16 which comprises the fuel cell 10 which concerns on 1st Embodiment, and the detailed description is abbreviate | omitted. In the third to eighth embodiments described below, the detailed description is omitted in the same manner.
[0054]
In the first separator 70, an oxidant gas supply side communication hole 72 and a fuel gas discharge side communication hole 74 are provided at one end edge in the arrow B direction. The oxidant gas supply side communication hole 72 and the fuel gas discharge side communication hole 74 have first linear portions 72a and 74a extending in a long shape in the direction of arrow B, and first extending in a long shape in the direction of arrow C. Two straight portions 72b and 74b are individually provided. The first straight portions 72a and 74a and the second straight portions 72b and 74b are separated at the upper and lower corner portions of the first separator 70, and reinforcing rib portions 76 are formed at the respective corner portions.
[0055]
A fuel gas supply side communication hole 78 and an oxidant gas discharge side communication hole 80 are provided at the other end edge of the first separator 70 in the arrow B direction. The fuel gas supply side communication hole 78 and the oxidant gas discharge side communication hole 80 have first straight portions 78a and 80a and second straight portions 78b and 80b that extend in the arrow B direction and the arrow C direction, respectively. Prepare individually. The first straight portions 78 a and 80 a and the second straight portions 78 b and 80 b are separated from each other, and rib portions 76 are formed corresponding to the upper and lower corner portions of the first separator 70.
[0056]
In the second embodiment configured as described above, the same effects as those of the first embodiment can be obtained, and rib portions 76 are formed at the four corners of the first separator 70. Therefore, the four corners of the 1st separator 70 are favorably reinforced by the rib part 76, and there exists an advantage that the intensity | strength of the said 1st separator 70 improves.
[0057]
FIG. 7 is an explanatory front view of the first separator 82 constituting the fuel cell according to the third embodiment of the present invention.
[0058]
The first separator 82 is provided with an oxidant gas supply side communication hole 84 and a fuel gas discharge side communication hole 86 at one end edge in the arrow B direction. The oxidant gas supply side communication hole 84 and the fuel gas discharge side communication hole 86 extend in a long shape in the direction of arrow B, and have a first linear portion 84 a having an inclined protrusion toward the corner of the first separator 82. , 86a, and second linear portions 84b, 86b that extend in the direction of the arrow C and have inclined protrusions toward the corners of the first separator 82, respectively. The first straight portions 84a and 86a and the second straight portions 84b and 86b are separated at both upper and lower corner portions of the first separator 82, and reinforcing rib portions 88 are formed at the respective corner portions.
[0059]
A fuel gas supply side communication hole 90 and an oxidant gas discharge side communication hole 92 are provided at the other end edge of the first separator 82 in the arrow B direction. The fuel gas supply side communication hole 90 and the oxidant gas discharge side communication hole 92 extend in a long shape in the direction of the arrow B and the direction of the arrow C, respectively, and have inclined protrusions toward the corners of the first separator 82. The first straight portions 90a and 92a and the second straight portions 90b and 92b are individually provided. The first straight portions 90 a and 92 a and the second straight portions 90 b and 92 b are separated from each other, and rib portions 88 are formed corresponding to the upper and lower corner portions of the first separator 82.
[0060]
In the third embodiment configured as above, the first straight portions 84a, 86a, 90a, 92a and the second straight portions 84b, 86b, 90b, 92b are inclined protrusions toward the four corners of the first separator 82, respectively. have. Therefore, the opening area of the oxidant gas supply side communication hole 84, the fuel gas discharge side communication hole 86, the fuel gas supply side communication hole 90, and the oxidant gas discharge side communication hole 92 can be expanded, and the electrode surface utilization rate The effect that (the electrode surface area with respect to the plane area of the 1st separator 82) improves effectively is acquired.
[0061]
FIG. 8 is an explanatory front view of the first separator 100 constituting the fuel cell according to the fourth embodiment of the present invention.
[0062]
In the first separator 100, an oxidant gas supply side communication hole 102 and a fuel gas discharge side communication hole 104 are provided at one end edge in the arrow B direction. The oxidant gas supply side communication hole 102 and the fuel gas discharge side communication hole 104 have first straight portions 102a and 104a extending in a long shape in the direction of arrow B, and first extending in a long shape in the direction of arrow C. Two straight portions 102b and 104b are individually provided.
[0063]
The first straight portions 102a, 104a and the second straight portions 102b, 104b are separated at the upper and lower corner portions of the first separator 100, and reinforcing rib portions 105 are formed at the respective corner portions. The rib portion 105 is formed with a hole portion 106 as a stack fastening bolt hole (or positioning knock hole).
[0064]
A fuel gas supply side communication hole 108 and an oxidant gas discharge side communication hole 110 are provided at the other end edge of the first separator 100 in the arrow B direction. The fuel gas supply side communication hole 108 and the oxidant gas discharge side communication hole 110 are provided with first straight portions 108a and 110a and second straight portions 108b and 110b extending in a long shape in the direction of the arrow B and the direction of the arrow C, respectively. Prepare individually.
[0065]
The first straight portions 108 a and 110 a and the second straight portions 108 b and 110 b are separated from each other, and the rib portions 105 are formed corresponding to the upper and lower corner portions of the first separator 100. The rib portion 105 is formed with a hole portion 106 as a stack fastening bolt hole (or positioning knock hole).
[0066]
In the fourth embodiment configured as described above, the same effects as in the second embodiment can be obtained, and holes 106 are formed at the four corners of the first separator 100, and the holes 106 are used. The entire fuel cell can be tightened or positioned.
[0067]
FIG. 9 is an explanatory front view of the first separator 120 constituting the fuel cell according to the fifth embodiment of the present invention.
[0068]
At one edge of the first separator 120 in the arrow B direction, an oxidant gas supply side communication hole 122, a cooling medium supply side communication hole 124, and a fuel gas discharge side communication hole 126 are provided. A fuel gas supply side communication hole 128, a cooling medium discharge side communication hole 130, and an oxidant gas discharge side communication hole 132 are provided at the other end edge of the first gas. The oxidant gas supply side communication hole 122 and the fuel gas discharge side communication hole 126 include first straight portions 122a and 126a extending in the direction of arrow B and second straight portions 122b and 126b extending in the direction of arrow C. Provide one. The first straight portions 122 a and 126 a are configured to be relatively long toward a substantially central portion of the first separator 120.
[0069]
Similarly, the fuel gas supply side communication hole 128 and the oxidant gas discharge side communication hole 132 have first straight portions 128a and 132a extending in the arrow B direction and second straight portions 128b and 132b extending in the arrow C direction. And are integrated. The first straight portions 128 a and 132 a are configured to be relatively long toward a substantially middle portion of the first separator 120.
[0070]
In the fifth embodiment, the first straight portions 122 a and 126 a and the first straight portions 128 a and 132 a are configured to be relatively long toward a substantially middle portion of the first separator 120. Therefore, the oxidant gas supply side communication hole 122 and the oxidant gas discharge side communication hole 132 are arranged close to each other, and the fuel gas supply side communication hole 128 and the fuel gas discharge side communication hole 126 are close to each other. The pressure loss of the fuel gas can be favorably reduced.
[0071]
FIG. 10 shows the present invention. Related to It is front explanatory drawing of the 1st separator 140 which comprises a fuel cell.
[0072]
In the first separator 140, an oxidant gas supply side communication hole 20 and an oxidant gas discharge side communication hole 26 are provided at one end edge in the arrow B direction, and fuel gas is provided at the other end edge in the arrow B direction. A supply side communication hole 24 and a fuel gas discharge side communication hole 22 are provided.
[0073]
An oxidant gas flow path (reaction gas flow path) 142 is formed on the surface 140 a of the first separator 140. The oxidant gas flow path 142 is located close to the oxidant gas supply side communication hole 20 and the oxidant gas discharge side communication hole 26, that is, above and below one edge of the first separator 140 in the arrow B direction. , First and second buffer units 144a and 144b. The first and second buffer portions 144a and 144b communicate with each other through a plurality of oxidant gas flow channel grooves 146, and the oxidant gas flow channel grooves 146 constitute a substantially U-shaped passage. Yes.
[0074]
FIG. 11 shows the present invention. Related to It is front explanatory drawing of the 1st separator 150 which comprises a fuel cell.
[0075]
The first separator 150 is configured by combining the first separator 120 and the first separator 140 described above, and an oxidant gas supply side communication hole 122 and a cooling medium supply side communication hole 124 at one end edge in the direction of arrow B. In addition, an oxidant gas discharge side communication hole 132 is provided. A fuel gas supply side communication hole 128, a coolant discharge side communication hole 130, and a fuel gas discharge side communication hole 126 are provided at the other end edge of the first separator 150 in the arrow B direction.
[0076]
FIG. 12 shows the first of the present invention. 6 It is front explanatory drawing of the 1st separator 160 which comprises the fuel cell which concerns on this embodiment.
[0077]
The first separator 160 is set in a substantially square shape, and an oxidant gas supply side communication hole 162 and a fuel gas discharge side communication hole 164 are provided at one end edge in the arrow B direction of the first separator 160. It is done.
[0078]
The oxidant gas supply side communication hole 162 is integrally provided with a first straight portion 162a that extends in the direction of the arrow B and a second straight portion 162b that extends in the direction of the arrow C. The fuel gas discharge side communication hole 164 extends in a long shape in the arrow B direction.
[0079]
A fuel gas supply side communication hole 166 and an oxidant gas discharge side communication hole 168 are provided at the other end edge of the first separator 160 in the arrow B direction. The fuel gas supply side communication hole 166 and the oxidant gas discharge side communication hole 168 have first straight portions 166a, 168a and second straight portions 166b, 168b extending in the arrow B direction and the arrow C direction, respectively. Provide one.
[0080]
The oxidant gas supply side communication hole 162 has a larger opening cross-sectional area than the oxidant gas discharge side communication hole 168, and the fuel gas supply side communication hole 166 is more open than the fuel gas discharge side communication hole 164. The area is set large.
[0081]
An oxidant gas flow path (reaction gas flow path) 170 is formed on the surface 160a of the first separator 160 facing the cathode electrode (not shown). The oxidant gas flow path 170 includes first and second buffer portions 172a and 172b provided close to the oxidant gas supply side communication hole 162 and the oxidant gas discharge side communication hole 168, and the first and second buffers. And a plurality of substantially straight oxidant gas flow channel grooves 174 communicating with the portions 172a and 172b and extending in parallel with each other in the direction of arrow B. Here, the term “substantially linear” includes those having undulations in a curved shape or a wave shape along the flow direction of the oxidizing gas (reactive gas).
[0082]
The inlet side end position T1 of the oxidant gas flow path 170 is set to substantially the same position as the end position of the first straight part 162a protruding in the arrow B direction of the oxidant gas supply side communication hole 162. The Similarly, the outlet side end portion position T2 of the oxidant gas flow path 170 is substantially the same position as the end portion position of the first straight portion 168a protruding in the arrow B direction of the oxidant gas discharge side communication hole 168. Set to
[0083]
Configured in this way 6 In this embodiment, the oxidant gas flow path 170 is provided with a plurality of oxidant gas flow path grooves 174 extending substantially linearly between the first and second buffer portions 172a and 172b. For this reason, the pressure loss of the oxidant gas in the oxidant gas flow path 170 is reduced as much as possible, and in particular, when the electrode area is set to a substantially square shape, the outer peripheral dimension of the first separator 160 is reduced. It can be set as small as possible, and there is an advantage that the heat retaining property of the first separator 160 is improved.
[0084]
Furthermore, the inlet side end position T1 of the oxidant gas flow path 170 is substantially the same as the end position of the first straight part 162a protruding toward the oxidant gas flow path 170 of the oxidant gas supply side communication hole 162. Are set at the same position. Here, when the end portion of the first straight portion 162a protrudes inward from the inlet side end position T1 of the oxidant gas channel 170 (see two points in FIG. 12). The oxidant gas may not flow into the oxidant gas flow path 170 from this end portion (see chain line).
[0085]
Accordingly, the end position of the first straight portion 162a is set to the same position as the inlet side end position T1 of the oxidant gas flow path 170, whereby the width direction of the oxidant gas flow path 170 (oxidant gas) is set. The oxidant gas can be made to flow uniformly in the direction perpendicular to the flow direction of the flow channel groove 174, and a good power generation function can be ensured.
[0086]
On the other hand, in the oxidant gas discharge side communication hole 168 as well, the end position of the first straight part 168a is set to be substantially the same position as the outlet side end position T2 of the oxidant gas flow path 170. As a result, the oxidant gas is smoothly discharged from the oxidant gas flow path 170 over the entire oxidant gas discharge side communication hole 168.
[0087]
Furthermore, the oxidant gas supply side communication hole 162 has a larger opening cross-sectional area than the oxidant gas discharge side communication hole 168. In the vicinity of the oxidant gas discharge side communication hole 168, the oxidant gas is consumed and the flow rate is reduced. For this reason, by setting the opening cross-sectional area of the oxidant gas discharge side communication hole 168 to be smaller than that of the oxidant gas supply side communication hole 162, the oxidant gas can flow smoothly.
[0088]
Similarly, the fuel gas supply side communication hole 166 has an opening cross-sectional area larger than that of the fuel gas discharge side communication hole 164, and the fuel gas that has been consumed and reduced in flow rate is supplied to the fuel gas discharge side communication hole 164. It can be discharged smoothly. At this time, the flow rate of the discharged fuel gas is considerably smaller than that of the oxidant gas, and the opening cross-sectional area of the fuel gas discharge side communication hole 164 can be set as small as possible.
[0089]
1st to 1st 6 In this embodiment, the flow direction of the reactive gas, which is the oxidant gas and the fuel gas, is set from the upper side to the lower side. On the contrary, the reactive gas flows from the lower side to the upper side. May be.
[0090]
Further, although the stacking direction is set to the horizontal direction, the stacking direction may be set to the vertical direction.
[0091]
【The invention's effect】
In the fuel cell according to the present invention, since at least the communication gas supply or discharge communication hole includes the first and second straight portions extending in the two side directions of the separator, the reaction gas reacts from different directions. When supplied to the gas flow path, they collide with each other and are uniformly dispersed in the reaction gas flow path. For this reason, it becomes possible to supply reaction gas uniformly and reliably with respect to an electrode surface. Moreover, the range of the passage for guiding the reaction gas from the communication hole to the electrode surface is greatly increased as compared with the conventional structure. Therefore, the pressure loss of the reaction gas in the passage is effectively reduced, the compressor for supplying the reaction gas is not increased in size, and the cell structure can be easily thinned.
[0092]
And since a communicating hole is arrange | positioned around the said separator including the corner | angular part of a separator, the electrode surface utilization factor of the said separator improves effectively. As a result, the entire fuel cell can be reduced in size and weight.
[0093]
Further, the electrode surface is surrounded by a communication hole arranged around the separator, and the electrode surface is not directly cooled by the outside air, and it is possible to prevent the occurrence of condensation in the electrode surface. it can. For this reason, it is possible to reduce the amount of condensed water in the electrode surface and to prevent the power generation performance from being lowered.
[Brief description of the drawings]
FIG. 1 is an exploded perspective view of a main part of a fuel cell according to a first embodiment of the present invention.
FIG. 2 is a partial cross-sectional view of the fuel cell.
FIG. 3 is an explanatory front view of a first separator constituting the fuel cell.
FIG. 4 is a front explanatory view of a second separator constituting the fuel cell.
FIG. 5 is a front explanatory view of the first separator provided with a circular buffer portion.
FIG. 6 is a front explanatory view of a first separator constituting a fuel cell according to a second embodiment of the present invention.
FIG. 7 is an explanatory front view of a first separator constituting a fuel cell according to a third embodiment of the present invention.
FIG. 8 is a front explanatory view of a first separator constituting a fuel cell according to a fourth embodiment of the present invention.
FIG. 9 is an explanatory front view of a first separator constituting a fuel cell according to a fifth embodiment of the present invention.
FIG. 10 shows the present invention. Related to It is front explanatory drawing of the 1st separator which comprises a fuel cell.
FIG. 11 shows the present invention. Related to It is front explanatory drawing of the 1st separator which comprises a fuel cell.
FIG. 12 shows the first of the present invention. 6 It is front explanatory drawing of the 1st separator which comprises the fuel cell which concerns on this embodiment.
13 is an explanatory front view of a separator according to Patent Document 1. FIG.
[Explanation of symbols]
10. Fuel cell
14 ... Electrolyte membrane / electrode structure
16, 18, 70, 82, 100, 120, 140, 150, 160 ... separator
19 ... Sealing member
20, 72, 84, 102, 122, 162 ... oxidant gas supply side communication hole
20a, 20b, 22a, 22b, 24a, 24b, 26a, 26b, 72a, 72b, 74a, 74b, 78a, 78b, 80a, 80b, 84a, 84b, 86a, 86b, 90a, 90b, 92a, 92b, 102a, 102b, 104a, 104b, 108a, 108b, 110a, 110b, 122a, 122b, 126a, 126b, 128a, 128b, 132a, 132b, 162a, 162b, 166a, 166b, 168a, 168b ... straight line portion
22, 74, 86, 104, 126, 164... Fuel gas discharge side communication hole
24, 78, 90, 108, 128, 166 ... Fuel gas supply side communication hole
26, 80, 92, 110, 132, 168... Oxidant gas discharge side communication hole
28, 124 ... Cooling medium supply side communication hole
30, 130 ... Cooling medium discharge side communication hole
32. Solid polymer electrolyte membrane
34 ... Anode side electrode
36 ... Cathode side electrode
38, 142, 170 ... oxidant gas flow path
40a, 40aa, 40b, 50a, 50b, 144a, 144b, 172a, 172b ... buffer section
42, 52, 146, 174 ... oxidant gas flow channel
48 ... Fuel gas flow path
76, 88, 105 ... rib part
106 ... hole

Claims (8)

A reaction gas formed in the separator surface facing the electrolyte / electrode structure, comprising an electrolyte / electrode structure having electrodes on both sides of the electrolyte and a pair of separators sandwiching the electrolyte / electrode structure A fuel cell in which a reaction gas supply side communication hole and a reaction gas discharge side communication hole are provided through the separator so as to supply and discharge at least a reaction gas that is an oxidant gas or a fuel gas in the flow path. Because
The planar shape of the separator is set to a substantially rectangular shape,
At least one of the reaction gas supply side communication holes and one of the reaction gas discharge side communication holes are provided across the respective corners of the diagonal position of the separator,
At least the reaction gas supply side communication hole includes first and second straight portions that extend in a two-sided direction across the corners of the separator, and the first and second straight portions extend from the first and second straight portions. The reaction gases supplied to the reaction gas flow path collide with each other,
The corner portion of the separator is provided with an inlet-side buffer portion and an outlet-side buffer portion that communicate the reaction gas flow channel with the reaction gas supply side communication hole and the reaction gas discharge side communication hole, and the reaction gas The flow path has a plurality of independent flow path grooves between the inlet side buffer section and the outlet side buffer section.   2. The fuel cell according to claim 1, wherein the first straight portion and the second straight portion are separated from each other across the corner portion of the separator, whereby a rib portion is provided between the first and second straight portions. A fuel cell comprising:   3. The fuel cell according to claim 2, wherein a hole for inserting a stack fastening bolt or a positioning knock is formed in the rib portion. 4. The fuel cell according to claim 1, wherein the separator has a cooling medium supply side communication hole and a cooling medium discharge side communication hole penetrating in the stacking direction in order to supply and discharge the cooling medium. 5. Is provided,
The reaction gas supply side communication hole, the reaction gas discharge side communication hole, the cooling medium supply side communication hole, and the cooling medium discharge side communication hole extend around the electrode surface of the electrolyte / electrode structure. A fuel cell.   5. The fuel cell according to claim 1, wherein the electrolyte / electrode structure and the separator are stacked in a horizontal direction. 6. The fuel cell according to claim 1 , wherein the planar shape of the separator is set to a substantially square shape,
In the separator surface, an inlet buffer portion and an outlet buffer portion are provided in proximity to at least one of the reactive gas supply side communication holes and one of the reactive gas discharge side communication holes,
The fuel cell according to claim 1, wherein the reaction gas flow path is provided in a substantially linear shape between the inlet buffer portion and the outlet buffer portion. 7. The fuel cell according to claim 6 , wherein at least an inlet side end position or an outlet side end position of the reactive gas flow path is at least the reactive gas flow in the reactive gas supply side communication hole or the reactive gas discharge side communication hole. A fuel cell, characterized in that the fuel cell is set at substantially the same position as an end position protruding toward the road. The fuel cell according to any one of claims 1 to 7, wherein the reaction gas supply communication hole, a fuel cell, characterized in that the aperture cross-section is set larger than the reaction gas discharge passage .

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